Effect of gelation conditions on the gel structure and resolving power of agarose-based DNA sequencing gels.

The effect of gelation conditions on the structure and resolving properties of agarose-based DNA sequencing gels were studied. Gels that were formed by rapid cooling gave separation patterns with sharp, well-defined bands, and resolved base repeats that were not separated on gels which were allowed to cool slowly. Analyses by electron microscopy indicated that the rapidly cooled gels have a homogeneous pore structure with a smaller average pore size than gels that were cooled slowly. The two types of gels also differ in optical clarity, and have significant differences in their melting characteristics as measured by differential scanning calorimetry.

Single-strand conformation polymorphism and heteroduplex analysis for gel-based mutation detection.

Single-strand conformation polymorphism (SSCP) and heteroduplex analysis (HA) are popular electrophoretic methods for the identification of sequences. The principle reasons for the popularity of these two methods are their technical simplicity and their relatively high sensitivity for the detection of mutations. Here we review the theory and practice of SSCP and HA, including the factors contributing to the sensitivity of mutation detection. For SSCP analysis, these factors include: choice of gel matrix, electrophoretic conditions, presence of neutral additives, fragment size, and G+C content For HA, the principle factors influencing sensitivity are the gel matrix and the identity of the base mismatch.

Use of a DNA toolbox for the characterization of mutation scanning methods. I: construction of the toolbox and evaluation of heteroduplex analysis.

A systematic characterization of the effects of important physical parameters on the sensitivity and specificity of methods in searching for unknown base changes (mutations or single nucleotide polymorphisms) over a relatively long DNA segment has not been previously reported. To this end, we have constructed a set of molecules of varying G+C content (40, 50, and 60% GC) having all possible base changes at a particular location - the "DNA toolbox". Exhaustive confirmatory sequencing demonstrated that there were no other base changes in any of the clones. Using this set of clones as polymerase chain reaction (PCR) templates, amplicons of various lengths with the same base mutated to all other bases were generated. The behavior of these constructs in manual and automated heteroduplex analysis was analyzed as a function of the size and overall base content of the fragment, the nature and location of the base change. Our results show that in heteroduplex analysis, the nature of the mismatched base pair is the overriding determinant for the ability to detect the mutation, regardless of fragment length, GC content, or the location of the mutation.

Use of DNA toolbox for the characterization of mutation scanning methods. II: evaluation of single-strand conformation polymorphism analysis.

Single-strand conformation polymorphism (SSCP) is one of the most commonly used methods for searching for unknown base changes (mutations). In order to characterize systematically the effects of important physical parameters on the sensitivity and specificity of SSCP, we used the DNA toolbox constructed as described in the companion paper [2]. Using this set of DNA molecules as polymerase chain reaction (PCR) templates, amplicons of various lengths with the same base, mutated to all other bases, were generated. The behavior of these constructs in manual and automated SSCP was analyzed as a function of the size, overall base content of the fragment, nature and location of the base change, and the temperature and pH of electrophoresis. Our results demonstrate that all of these variables interact to determine the rate of detection of single-base changes, with the GC content being the predominant determinant of detection sensitivity.

GelStar nucleic acid gel stain: high sensitivity detection in gels.

GelStar nucleic acid gel stain can be used for sensitive fluorescent detection of both double-stranded (ds) and single-stranded (ss) DNAs, oligonucleotides and RNA in gels. The stain can be added to agarose gels at casting for immediate imaging after electrophoresis or can be used after electrophoresis with both agarose and acrylamide gels. GelStar stain is highly fluorescent only when bound to nucleic acids thus giving superior signal-to-noise ratios and obviating the need to destain the gel. The detection limits of GelStar strain are 20 pg for dsDNA, 25 pg for ssDNA and 10 ng for native or glyoxal-treated RNA.

SDS agarose gels for analysis of proteins.

A new agarose-based protein electrophoresis gel system is described. The system consists of a highly resolving agarose, MetaPhor XR (FMC BioProducts, Rockland, ME, USA) dissolved in urea and TBE buffer and a stacking gel composed of a high gel-strength agarose, SeaKem Gold (FMC BioProducts). TBE containing sodium dodecyl sulfate (SDS) is used as electrophoresis buffer. The disadvantages of traditional agarose gels have been overcome, and several advantages over polyacrylamide gels have been demonstrated. The system is capable of high-resolution separation of small proteins and has a dynamic separation range equivalent to a 4%-20% gradient polyacrylamide gel. Furthermore, the staining of protein bands by Coomassie Brilliant Blue is very uniform in this gel, and depending on the protein, higher detection sensitivity can be obtained compared to SDS polyacrylamide gels. In Western blotting, proteins are more efficiently transferred to the membrane from the agarose gel than from polyacrylamide gels. Finally, the exceptional stability of agarose allows for gels to be precast and stored for a year.

Agarose-based system for separation of short tandem repeat loci.

Short tandem repeats (STRs) are traditionally analyzed on large polyacrylamide electrophoresis gels. We demonstrate in this study that a small (10-cm-long, 1-mm-thick) agarose gel is sufficient for analysis of multiplexed samples for several commonly used STR loci. A system was developed using a high-resolution agarose, MetaPhor. Within an hour of electrophoresis, sufficient resolution was obtained to allow discrimination of triple-multiplexed STR loci. We show that this agarose is capable of resolving di- as well as tetranucleotide ladders. Using PCR conditions similar to those routinely used with sensitive detection systems, we found that direct staining of gels with SYBR Green I stain was comparable with silver staining, autoradiography or fluorescently tagged primers for sample detection and was considerably easier. This procedure significantly simplifies STR analysis and is much faster than many standard protocols.

Long PCR facilitates concise cloning and sequencing with a minimal tiling set of templates.

We demonstrate a rapid cloning and sequencing strategy for kilobase-size DNA segments using DNase I and long PCR. In a single-tube protocol, deletions were formed in a plasmid insert by two enzymatic cuts, one at a fixed site and one at random. The doubly cut molecules were recircularized to generate a library of plasmids carrying deletions of various sizes and transformed into E. coli. The plasmid inserts were directly amplified from transformant colonies by long PCR and sized on a high-resolution agarose gel. A minimal tiling set, selected from the amplified material, was used directly as templates for long-read sequencing. The system is useful for inserts up to about 3.5 kb for de novo sequencing (both strands) or 6 kb for confirmatory sequencing (one strand).

Agarose gel analysis of 15-40-kb PCR amplimers.

Accurate resolution of PCR products in the range of 15-40 kb may be obtained in agarose gels without pulsed field electrophoresis. A gel of 0.3% SeaKem Gold agarose cast on GelBond support film provides good resolution and sufficient get strength to reliably allow staining and photography. This paper describes a test system for Long PCR and demonstrates analysis of the PCR products on a gel run under standard low-voltage electrophoresis conditions.

In vitro catalysis of oxidative folding of disulfide-bonded proteins by the Escherichia coli dsbA (ppfA) gene product.

It was shown previously that the Escherichia coli gene ppfA (dsbA) encodes a periplasmic protein, and its inactivation leads to a deficiency in disulfide bond formation of envelope proteins (Kamitani, S., Akiyama, Y., and Ito, K. (1992) EMBO J. 11, 57-62; Bardwell, J. C. A., McGovern, K., and Beckwith, J. (1991) Cell 67, 581-589). The DsbA/PpfA protein was overproduced, purified, and examined for its activities in vitro. Its abundance in a wild-type cell was estimated to be about 850 molecules which probably exist as homodimers as suggested by size exclusion chromatography. Purified DsbA markedly stimulated disulfide bond formation of E. coli alkaline phosphatase, either in vitro synthesized or purified and denatured, as well as of reduced bovine ribonuclease A. The DsbA-catalyzed rapid disulfide bond formation occurred after a lag period which appeared to be determined by the redox state of the reaction mixture and concentration of DsbA. Inclusion of higher concentrations of oxidized glutathione or DsbA shortened the lag period. We propose that DsbA, which proved to directly catalyze disulfide bond formation, may also have a role in maintaining the bacterial periplasm oxidative.

Rapid and reliable protocol for direct sequencing of material amplified by the polymerase chain reaction.

A simple and reliable method is described for direct sequencing of material generated by the polymerase chain reaction. The protocol is based on the purification of the amplified double-stranded product by polyethylene glycol precipitation, annealing of primer with template by a "snap-cooling" procedure and sequencing by the dideoxy chain termination method with the use of Klenow fragment or Taq polymerase. The limit of the size of PCR products that can be sequenced is also discussed.

Effects of mutations in heat-shock genes groES and groEL on protein export in Escherichia coli.

Escherichia coli heat-shock proteins GroES and GroEL are essential cytoplasmic proteins, which have been termed 'chaperonins' because of their ability to assist protein assembly of bacteriophage capsids and multimeric enzymes of foreign origin. In this report we show that temperature-sensitive mutations in groES and groEL genes cause defective export of the plasmid-encoded beta-lactamase (Bla) in vivo. Since efficient translocation of proteins across biological membranes is thought to be supported by cytoplasmic factors that protect presecretory molecules from being misfolded, these results suggest that both GroES and GroEL proteins possess a chaperone function by which they facilitate export of Bla. The translocation of other secretory proteins, however, appears to depend minimally on GroE, suggesting that GroE interacts only with a specific class of secreted proteins.

Transient shut off of Escherichia coli heat shock protein synthesis upon temperature shift down.

A moderate downward shift in growth temperature (37 to 30 degrees C in strain B/r and 37 to 24 degrees C in strain K-12) was found to depress markedly the synthesis of major heat shock proteins GroEL and DnaK in E. coli. The depression was transient and cancelled gradually to a new steady state level, taking 60-80 min. The synthesis of beta-galactosidase directed by transcription initiated at the groE promoter behaved similarly, suggesting that this regulation, termed "reverse heat shock response", occurs at the transcriptional level.

Chromosomal genes essential for stable maintenance of the mini-F plasmid in Escherichia coli.

We have isolated mutants of Escherichia coli which do not support stable maintenance of mini-F plasmids (delta ccd rep+ sop+). These host mutations, named hop, were classified into five linkage groups on the E. coli chromosome. Genetic analyses of these hop mutations by Hfr mating and P1 transduction showed their loci on the E. coli genetic map to be as follows: hopA in the gyrB-tnaA region, hopB in the bglB-oriC region, hopD between 8 and 15 min, and hopE in the argA-thyA region. Kinetics of stability of the sop+ and delta sop mini-F plasmids in these hop mutants suggest that the hopA mutants are defective in partitioning of mini-F rather than in plasmid replication. The hopB, hopC, and hopD mutants were partially defective in replication of mini-F. The physical structure of the plasmid DNA was normal in hopA, B, C, and D mutants. Large amounts of linear multimers of plasmid DNA accumulated in mutants of the fifth linkage group (hopE). None of the hop mutations in any linkage group affected the normal growth of cells.

Isolation and characterization of Escherichia coli mutants that lack the heat shock sigma factor sigma 32.

The product of the Escherichia coli rpoH (htpR) gene, sigma 32, is required for heat-inducible transcription of the heat shock genes. Previous studies on the role of sigma 32 in growth at low temperature and in gene expression involved the use of nonsense and missense rpoH mutations and have led to ambiguous or conflicting results. To clarify the role of sigma 32 in cell physiology, we have constructed loss-of-function insertion and deletion mutations in rpoH. Strains lacking sigma 32 are extremely temperature sensitive and grow only at temperatures less than or equal to 20 degrees C. There is no transcription from the heat shock promoters preceding the htpG gene or the groESL and dnaKJ operons; however, several heat shock proteins are produced in the mutants. GroEL protein is present in the rpoH null mutants, but its synthesis is not inducible by a shift to high temperature. The low-level synthesis of GroEL results from transcription initiation at a minor sigma 70-controlled promoter for the groE operon. DnaK protein synthesis cannot be detected at low temperature, but can be detected after a shift to 42 degrees C. The mechanism of this heat-inducible synthesis is not known. We conclude that sigma 32 is required for cell growth at temperatures above 20 degrees C and is required for transcription from the heat shock promoters. Several heat shock proteins are synthesized in the absence of sigma 32, indicating that there are additional mechanisms controlling the synthesis of some heat shock proteins.

Heat shock protein GroE of Escherichia coli: key protective roles against thermal stress.

An Escherichia coli mutant lacking the heat shock sigma-factor (sigma 32) is defective in transcription from heat shock promoters and cannot grow at temperatures above 20 degrees C. To assess physiological roles of sigma 32 and heat shock proteins, we isolated and characterized a set of temperature-resistant revertants from this deletion (delta rpoH) mutant. Most of them were found to carry a DNA insertion in the groE upstream region, resulting in high-level synthesis of major heat shock proteins GroE (GroES and GroEL). The levels of GroE produced varied in different revertants and correlated well with the maximum permissive temperatures; the highest GroE producers (approximately 10% of total protein) grew up to 40 degrees C but not at 42 degrees C. An additional mutation causing hyperproduction of DnaK (hsp70 homolog) was required for growth at 42 degrees C. Such effects of GroE and DnaK on the sigma 32-deletion strains were also confirmed by using multicopy plasmids carrying groE or dnaK. Thus, GroE plays a key protective role in supporting growth at normal physiological temperatures (20-40 degrees C), whereas high levels of DnaK are required primarily at higher temperature.

Suppression of rpoH (htpR) mutations of Escherichia coli: heat shock response in suhA revertants.

Temperature-resistant pseudorevertants were isolated from rpoH (htpR) mutants of Escherichia coli K-12 that cannot grow at a high temperature owing to a deficiency in sigma 32 required for the induction of heat shock proteins. Among them was a class of revertants carrying a suppressor mutation, designated suhA, that suppressed all the nonsense and missense rpoH mutations tested. suhA is located at 77 min, about 1 min away from rpoH, on the genetic map. In contrast to the rpoH mutants, the suhA revertants that contained both rpoH (nonsense) and suhA mutations were fully or partially proficient in the induction of heat shock proteins upon exposure to a high temperature. Under these conditions, transcription from two heat shock promoters as determined by operon fusion was transiently activated. In one of the rpoH(Am) suhA revertants studied in detail, an increase in temperature caused the synthesis of significant amounts of sigma 32, accompanied by increased stability and accumulation of rpoH mRNAs. On the other hand, the same mutation (suhA6) only weakly suppressed the rpoH deletion mutant; however, two of the major heat shock genes, dnaK and groE, were apparently induced in the absence of sigma 32. Thus, suhA6 seems to bring about the induction of heat shock genes by at least two mechanisms, one increasing the level of sigma 32 synthesis, and the other activating some transcription factor other than sigma 32.

Partitioning of the F plasmid: overproduction of an essential protein for partition inhibits plasmid maintenance.

Multicopy plasmids carrying the sopB gene of the F plasmid inhibit stable inheritance of a coexisting mini-F plasmid. This incompatibility, termed IncG, is found to be caused by excess amounts of the SopB protein, which is essential for accurate partitioning of plasmid DNA molecules into daughter cells. A sopB-carrying multicopy plasmid that shows the IncG+ phenotype was mutagenized in vitro and IncG negative mutant plasmids were isolated. Among these amber and missense mutants of sopB, mutants with a low plasmid copy number and a mutant in the Shine-Dalgarno sequence for translation of the SopB protein were obtained. These results demonstrate that the IncG phenotype is caused by the SopB protein, and that the incompatibility is expressed only when the protein is overproduced. This suggests that the protein must be kept at appropriate concentrations to ensure stable maintenance of the plasmid.